Noetherian ring

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In algebra, a Noetherian ring is a ring with a condition on the lattice of ideals.

Definition

Let ${\displaystyle A}$ be a ring. The following conditions are equivalent:

1. The ring ${\displaystyle A}$ satisfies an ascending chain condition on the set of its ideals: that is, there is no infinite ascending chain of ideals ${\displaystyle I_{0}\subsetneq I_{1}\subsetneq I_{2}\subsetneq \ldots }$.
2. Every ideal of ${\displaystyle A}$ is finitely generated.
3. Every nonempty set of ideals of ${\displaystyle A}$ has a maximal element when considered as a partially ordered set with respect to inclusion.

When the above conditions are satisfied, ${\displaystyle A}$ is said to be Noetherian. Alternatively, the ring ${\displaystyle A}$ is Noetherian if is a Noetherian module when regarded as a module over itself.

A Noetherian domain is a Noetherian ring which is also an integral domain.

Examples

• A field is Noetherian, since its only ideals are (0) and (1).
• A principal ideal domain is Noetherian, since every ideal is generated by a single element.
  • The ring of integers Z
  • The polynomial ring over a field
• The ring of continuous functions from R to R is not Noetherian. There is an ascending sequence of ideals

${\displaystyle \langle 0\rangle \subset \langle x\rangle \subset \langle x,x-1\rangle \subset \langle x,x-1,x-2\rangle \subset \cdots .\,}$

Useful Criteria

If ${\displaystyle A}$ is a Noetherian ring, then we have the following useful results:

1. The quotient ${\displaystyle A/I}$ is Noetherian for any ideal ${\displaystyle I}$.
2. The localization of ${\displaystyle A}$ by a multiplicative subset ${\displaystyle S}$ is again Noetherian.
3. Hilbert's Basis Theorem: The polynomial ring ${\displaystyle A[X]}$ is Noetherian (hence so is ${\displaystyle A[X_{1},\ldots ,X_{n}]}$).

References

• Serge Lang (1993). Algebra, 3rd ed. Addison-Wesley, 186-187. ISBN 0-201-55540-9.